test/Transforms/Inline/always-inline.ll - llvm - Git at Google

 ; RUN: opt < %s -inline-threshold=0 -always-inline -S | FileCheck %s --check-prefix=CHECK --check-prefix=CHECK-CALL
 ;
 ; Ensure the threshold has no impact on these decisions.
 ; RUN: opt < %s -inline-threshold=20000000 -always-inline -S | FileCheck %s --check-prefix=CHECK --check-prefix=CHECK-CALL
 ; RUN: opt < %s -inline-threshold=-20000000 -always-inline -S | FileCheck %s --check-prefix=CHECK --check-prefix=CHECK-CALL
 ;
 ; The new pass manager doesn't re-use any threshold based infrastructure for
 ; the always inliner, but test that we get the correct result. The new PM
 ; always inliner also doesn't support inlining call-site alwaysinline
 ; annotations. It isn't clear that this is a reasonable use case for
 ; 'alwaysinline'.
 ; RUN: opt < %s -passes=always-inline -S | FileCheck %s --check-prefix=CHECK

 define internal i32 @inner1() alwaysinline {
 ; CHECK-NOT: @inner1(
   ret i32 1
 }
 define i32 @outer1() {
 ; CHECK-LABEL: @outer1(
 ; CHECK-NOT: call
 ; CHECK: ret

    %r = call i32 @inner1()
    ret i32 %r
 }

 ; The always inliner can't DCE arbitrary internal functions. PR2945
 define internal i32 @pr2945() nounwind {
 ; CHECK-LABEL: @pr2945(
   ret i32 0
 }

 define internal void @inner2(i32 %N) alwaysinline {
 ; CHECK-NOT: @inner2(
   %P = alloca i32, i32 %N
   ret void
 }
 define void @outer2(i32 %N) {
 ; The always inliner (unlike the normal one) should be willing to inline
 ; a function with a dynamic alloca into one without a dynamic alloca.
 ; rdar://6655932
 ;
 ; CHECK-LABEL: @outer2(
 ; CHECK-NOT: call void @inner2
 ; CHECK-NOT: call void @inner2
 ; CHECK: ret void

   call void @inner2( i32 %N )
   ret void
 }

 declare i32 @a() returns_twice
 declare i32 @b() returns_twice

 ; Cannot alwaysinline when that would introduce a returns_twice call.
 define internal i32 @inner3() alwaysinline {
 ; CHECK-LABEL: @inner3(
 entry:
   %call = call i32 @a() returns_twice
   %add = add nsw i32 1, %call
   ret i32 %add
 }
 define i32 @outer3() {
 entry:
 ; CHECK-LABEL: @outer3(
 ; CHECK-NOT: call i32 @a
 ; CHECK: ret

   %call = call i32 @inner3()
   %add = add nsw i32 1, %call
   ret i32 %add
 }

 define internal i32 @inner4() alwaysinline returns_twice {
 ; CHECK-NOT: @inner4(
 entry:
   %call = call i32 @b() returns_twice
   %add = add nsw i32 1, %call
   ret i32 %add
 }

 define i32 @outer4() {
 entry:
 ; CHECK-LABEL: @outer4(
 ; CHECK: call i32 @b()
 ; CHECK: ret

   %call = call i32 @inner4() returns_twice
   %add = add nsw i32 1, %call
   ret i32 %add
 }

 ; We can't inline this even though it has alwaysinline!
 define internal i32 @inner5(i8* %addr) alwaysinline {
 ; CHECK-LABEL: @inner5(
 entry:
   indirectbr i8* %addr, [ label %one, label %two ]

 one:
   ret i32 42

 two:
   ret i32 44
 }
 define i32 @outer5(i32 %x) {
 ; CHECK-LABEL: @outer5(
 ; CHECK: call i32 @inner5
 ; CHECK: ret

   %cmp = icmp slt i32 %x, 42
   %addr = select i1 %cmp, i8* blockaddress(@inner5, %one), i8* blockaddress(@inner5, %two)
   %call = call i32 @inner5(i8* %addr)
   ret i32 %call
 }

 ; We alwaysinline a function that call itself recursively.
 define internal void @inner6(i32 %x) alwaysinline {
 ; CHECK-LABEL: @inner6(
 entry:
   %icmp = icmp slt i32 %x, 0
   br i1 %icmp, label %return, label %bb

 bb:
   %sub = sub nsw i32 %x, 1
   call void @inner6(i32 %sub)
   ret void

 return:
   ret void
 }
 define void @outer6() {
 ; CHECK-LABEL: @outer6(
 ; CHECK: call void @inner6(i32 42)
 ; CHECK: ret

 entry:
   call void @inner6(i32 42)
   ret void
 }

 ; This is not an alwaysinline function and is actually external.
 define i32 @inner7() {
 ; CHECK-LABEL: @inner7(
   ret i32 1
 }
 define i32 @outer7() {
 ; CHECK-CALL-LABEL: @outer7(
 ; CHECK-CALL-NOT: call
 ; CHECK-CALL: ret

    %r = call i32 @inner7() alwaysinline
    ret i32 %r
 }

 define internal float* @inner8(float* nocapture align 128 %a) alwaysinline {
 ; CHECK-NOT: @inner8(
   ret float* %a
 }
 define float @outer8(float* nocapture %a) {
 ; CHECK-LABEL: @outer8(
 ; CHECK-NOT: call float* @inner8
 ; CHECK: ret

   %inner_a = call float* @inner8(float* %a)
   %f = load float, float* %inner_a, align 4
   ret float %f
 }


 ; The 'inner9*' and 'outer9' functions are designed to check that we remove
 ; a function that is inlined by the always inliner even when it is used by
 ; a complex constant expression prior to being inlined.

 ; The 'a' function gets used in a complex constant expression that, despite
 ; being constant folded, means it isn't dead. As a consequence it shouldn't be
 ; deleted. If it is, then the constant expression needs to become more complex
 ; to accurately test this scenario.
 define internal void @inner9a(i1 %b) alwaysinline {
 ; CHECK-LABEL: @inner9a(
 entry:
   ret void
 }

 define internal void @inner9b(i1 %b) alwaysinline {
 ; CHECK-NOT: @inner9b(
 entry:
   ret void
 }

 declare void @dummy9(i1 %b)

 define void @outer9() {
 ; CHECK-LABEL: @outer9(
 entry:
   ; First we use @inner9a in a complex constant expression that may get folded
   ; but won't get removed, and then we call it which will get inlined. Despite
   ; this the function can't be deleted because of the constant expression
   ; usage.
   %sink = alloca i1
   store volatile i1 icmp eq (i64 ptrtoint (void (i1)* @inner9a to i64), i64 ptrtoint(void (i1)* @dummy9 to i64)), i1* %sink
 ; CHECK: store volatile
   call void @inner9a(i1 false)
 ; CHECK-NOT: call void @inner9a

   ; Next we call @inner9b passing in a constant expression. This constant
   ; expression will in fact be removed by inlining, so we should also be able
   ; to delete the function.
   call void @inner9b(i1 icmp eq (i64 ptrtoint (void (i1)* @inner9b to i64), i64 ptrtoint(void (i1)* @dummy9 to i64)))
 ; CHECK-NOT: @inner9b

   ret void
 ; CHECK: ret void
 }

 ; The 'inner10' and 'outer10' functions test a frustrating consquence of the
 ; current 'alwaysinline' semantic model. Because such functions are allowed to
 ; be external functions, it may be necessary to both inline all of their uses
 ; and leave them in the final output. These tests can be removed if and when
 ; we restrict alwaysinline further.
 define void @inner10() alwaysinline {
 ; CHECK-LABEL: @inner10(
 entry:
   ret void
 }

 define void @outer10() {
 ; CHECK-LABEL: @outer10(
 entry:
   call void @inner10()
 ; CHECK-NOT: call void @inner10

   ret void
 ; CHECK: ret void
 }

 ; The 'inner11' and 'outer11' functions test another dimension of non-internal
 ; functions with alwaysinline. These functions use external linkages that we can
 ; actually remove safely and so we should.
 define linkonce void @inner11a() alwaysinline {
 ; CHECK-NOT: @inner11a(
 entry:
   ret void
 }

 define available_externally void @inner11b() alwaysinline {
 ; CHECK-NOT: @inner11b(
 entry:
   ret void
 }

 define void @outer11() {
 ; CHECK-LABEL: @outer11(
 entry:
   call void @inner11a()
   call void @inner11b()
 ; CHECK-NOT: call void @inner11a
 ; CHECK-NOT: call void @inner11b

   ret void
 ; CHECK: ret void
 }

 ; The 'inner12' and 'outer12' functions test that we don't remove functions
 ; which are part of a comdat group even if they otherwise seem dead.
 $comdat12 = comdat any

 define linkonce void @inner12() alwaysinline comdat($comdat12) {
 ; CHECK-LABEL: @inner12(
   ret void
 }

 define void @outer12() comdat($comdat12) {
 ; CHECK-LABEL: @outer12(
 entry:
   call void @inner12()
 ; CHECK-NOT: call void @inner12

   ret void
 ; CHECK: ret void
 }

 ; The 'inner13*' and 'outer13' functions test that we do remove functions
 ; which are part of a comdat group where all of the members are removed during
 ; always inlining.
 $comdat13 = comdat any

 define linkonce void @inner13a() alwaysinline comdat($comdat13) {
 ; CHECK-NOT: @inner13a(
   ret void
 }

 define linkonce void @inner13b() alwaysinline comdat($comdat13) {
 ; CHECK-NOT: @inner13b(
   ret void
 }

 define void @outer13() {
 ; CHECK-LABEL: @outer13(
 entry:
   call void @inner13a()
   call void @inner13b()
 ; CHECK-NOT: call void @inner13a
 ; CHECK-NOT: call void @inner13b

   ret void
 ; CHECK: ret void
 }

 define void @inner14() readnone nounwind {
 ; CHECK: define void @inner14
   ret void
 }

 define void @outer14() {
 ; CHECK: call void @inner14
   call void @inner14()
   ret void
 }
	; RUN: opt < %s -inline-threshold=0 -always-inline -S \| FileCheck %s --check-prefix=CHECK --check-prefix=CHECK-CALL
	;
	; Ensure the threshold has no impact on these decisions.
	; RUN: opt < %s -inline-threshold=20000000 -always-inline -S \| FileCheck %s --check-prefix=CHECK --check-prefix=CHECK-CALL
	; RUN: opt < %s -inline-threshold=-20000000 -always-inline -S \| FileCheck %s --check-prefix=CHECK --check-prefix=CHECK-CALL
	;
	; The new pass manager doesn't re-use any threshold based infrastructure for
	; the always inliner, but test that we get the correct result. The new PM
	; always inliner also doesn't support inlining call-site alwaysinline
	; annotations. It isn't clear that this is a reasonable use case for
	; 'alwaysinline'.
	; RUN: opt < %s -passes=always-inline -S \| FileCheck %s --check-prefix=CHECK

	define internal i32 @inner1() alwaysinline {
	; CHECK-NOT: @inner1(
	ret i32 1
	}
	define i32 @outer1() {
	; CHECK-LABEL: @outer1(
	; CHECK-NOT: call
	; CHECK: ret

	%r = call i32 @inner1()
	ret i32 %r
	}

	; The always inliner can't DCE arbitrary internal functions. PR2945
	define internal i32 @pr2945() nounwind {
	; CHECK-LABEL: @pr2945(
	ret i32 0
	}

	define internal void @inner2(i32 %N) alwaysinline {
	; CHECK-NOT: @inner2(
	%P = alloca i32, i32 %N
	ret void
	}
	define void @outer2(i32 %N) {
	; The always inliner (unlike the normal one) should be willing to inline
	; a function with a dynamic alloca into one without a dynamic alloca.
	; rdar://6655932
	;
	; CHECK-LABEL: @outer2(
	; CHECK-NOT: call void @inner2
	; CHECK-NOT: call void @inner2
	; CHECK: ret void

	call void @inner2( i32 %N )
	ret void
	}

	declare i32 @a() returns_twice
	declare i32 @b() returns_twice

	; Cannot alwaysinline when that would introduce a returns_twice call.
	define internal i32 @inner3() alwaysinline {
	; CHECK-LABEL: @inner3(
	entry:
	%call = call i32 @a() returns_twice
	%add = add nsw i32 1, %call
	ret i32 %add
	}
	define i32 @outer3() {
	entry:
	; CHECK-LABEL: @outer3(
	; CHECK-NOT: call i32 @a
	; CHECK: ret

	%call = call i32 @inner3()
	%add = add nsw i32 1, %call
	ret i32 %add
	}

	define internal i32 @inner4() alwaysinline returns_twice {
	; CHECK-NOT: @inner4(
	entry:
	%call = call i32 @b() returns_twice
	%add = add nsw i32 1, %call
	ret i32 %add
	}

	define i32 @outer4() {
	entry:
	; CHECK-LABEL: @outer4(
	; CHECK: call i32 @b()
	; CHECK: ret

	%call = call i32 @inner4() returns_twice
	%add = add nsw i32 1, %call
	ret i32 %add
	}

	; We can't inline this even though it has alwaysinline!
	define internal i32 @inner5(i8* %addr) alwaysinline {
	; CHECK-LABEL: @inner5(
	entry:
	indirectbr i8* %addr, [ label %one, label %two ]

	one:
	ret i32 42

	two:
	ret i32 44
	}
	define i32 @outer5(i32 %x) {
	; CHECK-LABEL: @outer5(
	; CHECK: call i32 @inner5
	; CHECK: ret

	%cmp = icmp slt i32 %x, 42
	%addr = select i1 %cmp, i8* blockaddress(@inner5, %one), i8* blockaddress(@inner5, %two)
	%call = call i32 @inner5(i8* %addr)
	ret i32 %call
	}

	; We alwaysinline a function that call itself recursively.
	define internal void @inner6(i32 %x) alwaysinline {
	; CHECK-LABEL: @inner6(
	entry:
	%icmp = icmp slt i32 %x, 0
	br i1 %icmp, label %return, label %bb

	bb:
	%sub = sub nsw i32 %x, 1
	call void @inner6(i32 %sub)
	ret void

	return:
	ret void
	}
	define void @outer6() {
	; CHECK-LABEL: @outer6(
	; CHECK: call void @inner6(i32 42)
	; CHECK: ret

	entry:
	call void @inner6(i32 42)
	ret void
	}

	; This is not an alwaysinline function and is actually external.
	define i32 @inner7() {
	; CHECK-LABEL: @inner7(
	ret i32 1
	}
	define i32 @outer7() {
	; CHECK-CALL-LABEL: @outer7(
	; CHECK-CALL-NOT: call
	; CHECK-CALL: ret

	%r = call i32 @inner7() alwaysinline
	ret i32 %r
	}

	define internal float* @inner8(float* nocapture align 128 %a) alwaysinline {
	; CHECK-NOT: @inner8(
	ret float* %a
	}
	define float @outer8(float* nocapture %a) {
	; CHECK-LABEL: @outer8(
	; CHECK-NOT: call float* @inner8
	; CHECK: ret

	%inner_a = call float* @inner8(float* %a)
	%f = load float, float* %inner_a, align 4
	ret float %f
	}


	; The 'inner9*' and 'outer9' functions are designed to check that we remove
	; a function that is inlined by the always inliner even when it is used by
	; a complex constant expression prior to being inlined.

	; The 'a' function gets used in a complex constant expression that, despite
	; being constant folded, means it isn't dead. As a consequence it shouldn't be
	; deleted. If it is, then the constant expression needs to become more complex
	; to accurately test this scenario.
	define internal void @inner9a(i1 %b) alwaysinline {
	; CHECK-LABEL: @inner9a(
	entry:
	ret void
	}

	define internal void @inner9b(i1 %b) alwaysinline {
	; CHECK-NOT: @inner9b(
	entry:
	ret void
	}

	declare void @dummy9(i1 %b)

	define void @outer9() {
	; CHECK-LABEL: @outer9(
	entry:
	; First we use @inner9a in a complex constant expression that may get folded
	; but won't get removed, and then we call it which will get inlined. Despite
	; this the function can't be deleted because of the constant expression
	; usage.
	%sink = alloca i1
	store volatile i1 icmp eq (i64 ptrtoint (void (i1)* @inner9a to i64), i64 ptrtoint(void (i1)* @dummy9 to i64)), i1* %sink
	; CHECK: store volatile
	call void @inner9a(i1 false)
	; CHECK-NOT: call void @inner9a

	; Next we call @inner9b passing in a constant expression. This constant
	; expression will in fact be removed by inlining, so we should also be able
	; to delete the function.
	call void @inner9b(i1 icmp eq (i64 ptrtoint (void (i1)* @inner9b to i64), i64 ptrtoint(void (i1)* @dummy9 to i64)))
	; CHECK-NOT: @inner9b

	ret void
	; CHECK: ret void
	}

	; The 'inner10' and 'outer10' functions test a frustrating consquence of the
	; current 'alwaysinline' semantic model. Because such functions are allowed to
	; be external functions, it may be necessary to both inline all of their uses
	; and leave them in the final output. These tests can be removed if and when
	; we restrict alwaysinline further.
	define void @inner10() alwaysinline {
	; CHECK-LABEL: @inner10(
	entry:
	ret void
	}

	define void @outer10() {
	; CHECK-LABEL: @outer10(
	entry:
	call void @inner10()
	; CHECK-NOT: call void @inner10

	ret void
	; CHECK: ret void
	}

	; The 'inner11' and 'outer11' functions test another dimension of non-internal
	; functions with alwaysinline. These functions use external linkages that we can
	; actually remove safely and so we should.
	define linkonce void @inner11a() alwaysinline {
	; CHECK-NOT: @inner11a(
	entry:
	ret void
	}

	define available_externally void @inner11b() alwaysinline {
	; CHECK-NOT: @inner11b(
	entry:
	ret void
	}

	define void @outer11() {
	; CHECK-LABEL: @outer11(
	entry:
	call void @inner11a()
	call void @inner11b()
	; CHECK-NOT: call void @inner11a
	; CHECK-NOT: call void @inner11b

	ret void
	; CHECK: ret void
	}

	; The 'inner12' and 'outer12' functions test that we don't remove functions
	; which are part of a comdat group even if they otherwise seem dead.
	$comdat12 = comdat any

	define linkonce void @inner12() alwaysinline comdat($comdat12) {
	; CHECK-LABEL: @inner12(
	ret void
	}

	define void @outer12() comdat($comdat12) {
	; CHECK-LABEL: @outer12(
	entry:
	call void @inner12()
	; CHECK-NOT: call void @inner12

	ret void
	; CHECK: ret void
	}

	; The 'inner13*' and 'outer13' functions test that we do remove functions
	; which are part of a comdat group where all of the members are removed during
	; always inlining.
	$comdat13 = comdat any

	define linkonce void @inner13a() alwaysinline comdat($comdat13) {
	; CHECK-NOT: @inner13a(
	ret void
	}

	define linkonce void @inner13b() alwaysinline comdat($comdat13) {
	; CHECK-NOT: @inner13b(
	ret void
	}

	define void @outer13() {
	; CHECK-LABEL: @outer13(
	entry:
	call void @inner13a()
	call void @inner13b()
	; CHECK-NOT: call void @inner13a
	; CHECK-NOT: call void @inner13b

	ret void
	; CHECK: ret void
	}

	define void @inner14() readnone nounwind {
	; CHECK: define void @inner14
	ret void
	}

	define void @outer14() {
	; CHECK: call void @inner14
	call void @inner14()
	ret void
	}